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Dependencies: MAX44000 nexpaq_mdk
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mbd_os/tools/memap.py
- Committer:
- nexpaq
- Date:
- 2016-09-17
- Revision:
- 1:55a6170b404f
File content as of revision 1:55a6170b404f:
#!/usr/bin/env python """Memory Map File Analyser for ARM mbed""" import sys import os import re import csv import json import argparse from prettytable import PrettyTable from tools.utils import argparse_filestring_type, \ argparse_lowercase_hyphen_type, argparse_uppercase_type DEBUG = False RE_ARMCC = re.compile( r'^\s+0x(\w{8})\s+0x(\w{8})\s+(\w+)\s+(\w+)\s+(\d+)\s+[*]?.+\s+(.+)$') RE_IAR = re.compile( r'^\s+(.+)\s+(zero|const|ro code|inited|uninit)\s' r'+0x(\w{8})\s+0x(\w+)\s+(.+)\s.+$') class MemapParser(object): """An object that represents parsed results, parses the memory map files, and writes out different file types of memory results """ print_sections = ('.text', '.data', '.bss') misc_flash_sections = ('.interrupts', '.flash_config') other_sections = ('.interrupts_ram', '.init', '.ARM.extab', '.ARM.exidx', '.ARM.attributes', '.eh_frame', '.init_array', '.fini_array', '.jcr', '.stab', '.stabstr', '.ARM.exidx', '.ARM') # sections to print info (generic for all toolchains) sections = ('.text', '.data', '.bss', '.heap', '.stack') def __init__(self): """ General initialization """ # list of all modules and their sections self.modules = dict() # sections must be defined in this order to take irrelevant out self.all_sections = self.sections + self.other_sections + \ self.misc_flash_sections + ('unknown', 'OUTPUT') # list of all object files and mappting to module names self.object_to_module = dict() # Memory usage summary structure self.mem_summary = dict() def module_add(self, module_name, size, section): """ Adds a module / section to the list Positional arguments: module_name - name of the module to add size - the size of the module being added section - the section the module contributes to """ if module_name in self.modules: self.modules[module_name][section] += size else: temp_dic = dict() for section_idx in self.all_sections: temp_dic[section_idx] = 0 temp_dic[section] = size self.modules[module_name] = temp_dic def check_new_section_gcc(self, line): """ Check whether a new section in a map file has been detected (only applies to gcc) Positional arguments: line - the line to check for a new section """ for i in self.all_sections: if line.startswith(i): # should name of the section (assuming it's a known one) return i if line.startswith('.'): return 'unknown' # all others are classified are unknown else: return False # everything else, means no change in section @staticmethod def path_object_to_module_name(txt): """ Parse a path to object file to extract it's module and object data Positional arguments: txt - the path to parse the object and module name from """ txt = txt.replace('\\', '/') rex_mbed_os_name = r'^.+mbed-os\/(.+)\/(.+\.o)$' test_rex_mbed_os_name = re.match(rex_mbed_os_name, txt) if test_rex_mbed_os_name: object_name = test_rex_mbed_os_name.group(2) data = test_rex_mbed_os_name.group(1).split('/') ndata = len(data) if ndata == 1: module_name = data[0] else: module_name = data[0] + '/' + data[1] return [module_name, object_name] else: return ['Misc', ""] def parse_section_gcc(self, line): """ Parse data from a section of gcc map file examples: 0x00004308 0x7c ./.build/K64F/GCC_ARM/mbed-os/hal/targets/hal/TARGET_Freescale/TARGET_KPSDK_MCUS/spi_api.o .text 0x00000608 0x198 ./.build/K64F/GCC_ARM/mbed-os/core/mbed-rtos/rtx/TARGET_CORTEX_M/TARGET_RTOS_M4_M7/TOOLCHAIN_GCC/HAL_CM4.o Positional arguments: line - the line to parse a section from """ rex_address_len_name = re.compile( r'^\s+.*0x(\w{8,16})\s+0x(\w+)\s(.+)$') test_address_len_name = re.match(rex_address_len_name, line) if test_address_len_name: if int(test_address_len_name.group(2), 16) == 0: # size == 0 return ["", 0] # no valid entry else: m_name, _ = self.path_object_to_module_name( test_address_len_name.group(3)) m_size = int(test_address_len_name.group(2), 16) return [m_name, m_size] else: # special corner case for *fill* sections # example # *fill* 0x0000abe4 0x4 rex_address_len = r'^\s+\*fill\*\s+0x(\w{8,16})\s+0x(\w+).*$' test_address_len = re.match(rex_address_len, line) if test_address_len: if int(test_address_len.group(2), 16) == 0: # size == 0 return ["", 0] # no valid entry else: m_name = 'Fill' m_size = int(test_address_len.group(2), 16) return [m_name, m_size] else: return ["", 0] # no valid entry def parse_map_file_gcc(self, file_desc): """ Main logic to decode gcc map files Positional arguments: file_desc - a stream object to parse as a gcc map file """ current_section = 'unknown' with file_desc as infile: # Search area to parse for line in infile: if line.startswith('Linker script and memory map'): current_section = "unknown" break # Start decoding the map file for line in infile: change_section = self.check_new_section_gcc(line) if change_section == "OUTPUT": # finish parsing file: exit break elif change_section != False: current_section = change_section [module_name, module_size] = self.parse_section_gcc(line) if module_size == 0 or module_name == "": pass else: self.module_add(module_name, module_size, current_section) if DEBUG: print "Line: %s" % line, print "Module: %s\tSection: %s\tSize: %s" % \ (module_name, current_section, module_size) raw_input("----------") def parse_section_armcc(self, line): """ Parse data from an armcc map file Examples of armcc map file: Base_Addr Size Type Attr Idx E Section Name Object 0x00000000 0x00000400 Data RO 11222 RESET startup_MK64F12.o 0x00000410 0x00000008 Code RO 49364 * !!!main c_w.l(__main.o) Positional arguments: line - the line to parse the section data from """ test_rex_armcc = re.match(RE_ARMCC, line) if test_rex_armcc: size = int(test_rex_armcc.group(2), 16) if test_rex_armcc.group(4) == 'RO': section = '.text' else: if test_rex_armcc.group(3) == 'Data': section = '.data' elif test_rex_armcc.group(3) == 'Zero': section = '.bss' else: print "BUG armcc map parser" raw_input() # lookup object in dictionary and return module name object_name = test_rex_armcc.group(6) if object_name in self.object_to_module: module_name = self.object_to_module[object_name] else: module_name = 'Misc' return [module_name, size, section] else: return ["", 0, ""] # no valid entry def parse_section_iar(self, line): """ Parse data from an IAR map file Examples of IAR map file: Section Kind Address Size Object .intvec ro code 0x00000000 0x198 startup_MK64F12.o [15] .rodata const 0x00000198 0x0 zero_init3.o [133] .iar.init_table const 0x00008384 0x2c - Linker created - Initializer bytes const 0x00000198 0xb2 <for P3 s0> .data inited 0x20000000 0xd4 driverAtmelRFInterface.o [70] .bss zero 0x20000598 0x318 RTX_Conf_CM.o [4] .iar.dynexit uninit 0x20001448 0x204 <Block tail> HEAP uninit 0x20001650 0x10000 <Block tail> Positional_arguments: line - the line to parse section data from """ test_rex_iar = re.match(RE_IAR, line) if test_rex_iar: size = int(test_rex_iar.group(4), 16) if test_rex_iar.group(2) == 'const' or \ test_rex_iar.group(2) == 'ro code': section = '.text' elif test_rex_iar.group(2) == 'zero' or \ test_rex_iar.group(2) == 'uninit': if test_rex_iar.group(1)[0:4] == 'HEAP': section = '.heap' elif test_rex_iar.group(1)[0:6] == 'CSTACK': section = '.stack' else: section = '.bss' # default section elif test_rex_iar.group(2) == 'inited': section = '.data' else: print "BUG IAR map parser" raw_input() # lookup object in dictionary and return module name object_name = test_rex_iar.group(5) if object_name in self.object_to_module: module_name = self.object_to_module[object_name] else: module_name = 'Misc' return [module_name, size, section] else: return ["", 0, ""] # no valid entry def parse_map_file_armcc(self, file_desc): """ Main logic to decode armc5 map files Positional arguments: file_desc - a file like object to parse as an armc5 map file """ with file_desc as infile: # Search area to parse for line in infile: if line.startswith(' Base Addr Size'): break # Start decoding the map file for line in infile: [name, size, section] = self.parse_section_armcc(line) if size == 0 or name == "" or section == "": pass else: self.module_add(name, size, section) def parse_map_file_iar(self, file_desc): """ Main logic to decode IAR map files Positional arguments: file_desc - a file like object to parse as an IAR map file """ with file_desc as infile: # Search area to parse for line in infile: if line.startswith(' Section '): break # Start decoding the map file for line in infile: [name, size, section] = self.parse_section_iar(line) if size == 0 or name == "" or section == "": pass else: self.module_add(name, size, section) def search_objects(self, path, toolchain): """ Check whether the specified map file matches with the toolchain. Searches for object files and creates mapping: object --> module Positional arguments: path - the path to an object file toolchain - the toolchain used to build the object file """ path = path.replace('\\', '/') # check location of map file rex = r'^(.+\/)' + re.escape(toolchain) + r'\/(.+\.map)$' test_rex = re.match(rex, path) if test_rex: search_path = test_rex.group(1) + toolchain + '/mbed-os/' else: # It looks this is not an mbed project # object-to-module mapping cannot be generated print "Warning: specified toolchain doesn't match with"\ " path to the memory map file." return for root, _, obj_files in os.walk(search_path): for obj_file in obj_files: if obj_file.endswith(".o"): module_name, object_name = self.path_object_to_module_name( os.path.join(root, obj_file)) if object_name in self.object_to_module: if DEBUG: print "WARNING: multiple usages of object file: %s"\ % object_name print " Current: %s" % \ self.object_to_module[object_name] print " New: %s" % module_name print " " else: self.object_to_module.update({object_name:module_name}) export_formats = ["json", "csv-ci", "table"] def generate_output(self, export_format, file_output=None): """ Generates summary of memory map data Positional arguments: export_format - the format to dump Keyword arguments: file_desc - descriptor (either stdout or file) """ try: if file_output: file_desc = open(file_output, 'wb') else: file_desc = sys.stdout except IOError as error: print "I/O error({0}): {1}".format(error.errno, error.strerror) return False subtotal = dict() for k in self.sections: subtotal[k] = 0 # Calculate misc flash sections misc_flash_mem = 0 for i in self.modules: for k in self.misc_flash_sections: if self.modules[i][k]: misc_flash_mem += self.modules[i][k] json_obj = [] for i in sorted(self.modules): row = [] json_obj.append({ "module":i, "size":{ k:self.modules[i][k] for k in self.print_sections } }) summary = { 'summary':{ 'static_ram': (subtotal['.data'] + subtotal['.bss']), 'heap': (subtotal['.heap']), 'stack': (subtotal['.stack']), 'total_ram': (subtotal['.data'] + subtotal['.bss'] + subtotal['.heap']+subtotal['.stack']), 'total_flash': (subtotal['.text'] + subtotal['.data'] + misc_flash_mem), } } self.mem_summary = json_obj + [summary] to_call = {'json': self.generate_json, 'csv-ci': self.generate_csv, 'table': self.generate_table}[export_format] to_call(subtotal, misc_flash_mem, file_desc) if file_desc is not sys.stdout: file_desc.close() def generate_json(self, _, dummy, file_desc): """Generate a json file from a memory map Positional arguments: subtotal - total sizes for each module misc_flash_mem - size of misc flash sections file_desc - the file to write out the final report to """ file_desc.write(json.dumps(self.mem_summary, indent=4)) file_desc.write('\n') def generate_csv(self, subtotal, misc_flash_mem, file_desc): """Generate a CSV file from a memoy map Positional arguments: subtotal - total sizes for each module misc_flash_mem - size of misc flash sections file_desc - the file to write out the final report to """ csv_writer = csv.writer(file_desc, delimiter=',', quoting=csv.QUOTE_NONE) csv_module_section = [] csv_sizes = [] for i in sorted(self.modules): for k in self.print_sections: csv_module_section += [i+k] csv_sizes += [self.modules[i][k]] csv_module_section += ['static_ram'] csv_sizes += [subtotal['.data']+subtotal['.bss']] csv_module_section += ['heap'] if subtotal['.heap'] == 0: csv_sizes += ['unknown'] else: csv_sizes += [subtotal['.heap']] csv_module_section += ['stack'] if subtotal['.stack'] == 0: csv_sizes += ['unknown'] else: csv_sizes += [subtotal['.stack']] csv_module_section += ['total_ram'] csv_sizes += [subtotal['.data'] + subtotal['.bss'] + subtotal['.heap'] + subtotal['.stack']] csv_module_section += ['total_flash'] csv_sizes += [subtotal['.text']+subtotal['.data']+misc_flash_mem] csv_writer.writerow(csv_module_section) csv_writer.writerow(csv_sizes) def generate_table(self, subtotal, misc_flash_mem, file_desc): """Generate a table from a memoy map Positional arguments: subtotal - total sizes for each module misc_flash_mem - size of misc flash sections file_desc - the file to write out the final report to """ # Create table columns = ['Module'] columns.extend(self.print_sections) table = PrettyTable(columns) table.align["Module"] = "l" for col in self.print_sections: table.align[col] = 'r' for i in list(self.print_sections): table.align[i] = 'r' for i in sorted(self.modules): row = [i] for k in self.sections: subtotal[k] += self.modules[i][k] for k in self.print_sections: row.append(self.modules[i][k]) table.add_row(row) subtotal_row = ['Subtotals'] for k in self.print_sections: subtotal_row.append(subtotal[k]) table.add_row(subtotal_row) file_desc.write(table.get_string()) file_desc.write('\n') if subtotal['.heap'] == 0: file_desc.write("Allocated Heap: unknown\n") else: file_desc.write("Allocated Heap: %s bytes\n" % str(subtotal['.heap'])) if subtotal['.stack'] == 0: file_desc.write("Allocated Stack: unknown\n") else: file_desc.write("Allocated Stack: %s bytes\n" % str(subtotal['.stack'])) file_desc.write("Total Static RAM memory (data + bss): %s bytes\n" % (str(subtotal['.data'] + subtotal['.bss']))) file_desc.write( "Total RAM memory (data + bss + heap + stack): %s bytes\n" % (str(subtotal['.data'] + subtotal['.bss'] + subtotal['.heap'] + subtotal['.stack']))) file_desc.write("Total Flash memory (text + data + misc): %s bytes\n" % (str(subtotal['.text'] + subtotal['.data'] + misc_flash_mem))) toolchains = ["ARM", "ARM_STD", "ARM_MICRO", "GCC_ARM", "IAR"] def parse(self, mapfile, toolchain): """ Parse and decode map file depending on the toolchain Positional arguments: mapfile - the file name of the memory map file toolchain - the toolchain used to create the file """ result = True try: with open(mapfile, 'r') as file_input: if toolchain == "ARM" or toolchain == "ARM_STD" or\ toolchain == "ARM_MICRO": self.search_objects(os.path.abspath(mapfile), "ARM") self.parse_map_file_armcc(file_input) elif toolchain == "GCC_ARM": self.parse_map_file_gcc(file_input) elif toolchain == "IAR": self.search_objects(os.path.abspath(mapfile), toolchain) self.parse_map_file_iar(file_input) else: result = False except IOError as error: print "I/O error({0}): {1}".format(error.errno, error.strerror) result = False return result def main(): """Entry Point""" version = '0.3.11' # Parser handling parser = argparse.ArgumentParser( description="Memory Map File Analyser for ARM mbed\nversion %s" % version) parser.add_argument( 'file', type=argparse_filestring_type, help='memory map file') parser.add_argument( '-t', '--toolchain', dest='toolchain', help='select a toolchain used to build the memory map file (%s)' % ", ".join(MemapParser.toolchains), required=True, type=argparse_uppercase_type(MemapParser.toolchains, "toolchain")) parser.add_argument( '-o', '--output', help='output file name', required=False) parser.add_argument( '-e', '--export', dest='export', required=False, default='table', type=argparse_lowercase_hyphen_type(MemapParser.export_formats, 'export format'), help="export format (examples: %s: default)" % ", ".join(MemapParser.export_formats)) parser.add_argument('-v', '--version', action='version', version=version) # Parse/run command if len(sys.argv) <= 1: parser.print_help() sys.exit(1) args = parser.parse_args() # Create memap object memap = MemapParser() # Parse and decode a map file if args.file and args.toolchain: if memap.parse(args.file, args.toolchain) is False: sys.exit(0) # Write output in file if args.output != None: memap.generate_output(args.export, args.output) else: # Write output in screen memap.generate_output(args.export) sys.exit(0) if __name__ == "__main__": main()